Aldehydic cores

Unsaturated di- and triglycerides also can be converted into aldehydic cores by reductive ozonolysis six of the seven diglyceride types and four of the six triglyceride types can then be determined by combina-... 

Saturated lecithins and the three types of aldehydic cores obtained by reductive ozonolysis of unsaturated lecithins can be separated through reversed phase partition chromatography [168]. Fig. 147 shows photo-densitometric curves from thin-layer chromatograms of fission products derived from the lecithins of egg, bovine spinal cord, soya bean and wheat germ. 

Fig. 147. Densitometric curves of the aldehydic cores from naturally occurring lecithin mixtures 168 Stationary phase silicone on silica gel G solvent acetic acid-water (80 20) time of run 1.5 h visualisation carbonisation by heating...

Triglycerides and esters of diols (diol lipids), compounds which cannot be separated by adsorption TLC, can be fractionated into classes through reversed phase partition TLC this applies equally to the corresponding alkoxylipids [9]. Chromatography on hydrophobic layers is also suitable for separating the aldehydic cores which are obtained from unsaturated lecithins by reductive ozonolysis [168] (see Fig. 147, p. 409) and for analysing sphingosine bases [129]. 

Many drugs and namral products are (or contain) macro-cyclic structures that require the synthesis, and functionalization, of large rings in an asymmetric fashion. At its simplest, this can involve immobilization of a preassembled macrocyclic core on a solid support, and subsequent modification. This approach was used by Sowin and colleagues to prepare a library of macrolide antibiotics. Aldehyde core 262, readily accessible from 6-0-allyl-erythromycin A, was immobilized on support 263 using a... 

Hoffmaim-La Roche has produced -carotene since the 1950s and has rehed on core knowledge of vitamin A chemistry for the synthesis of this target. In this approach, a five-carbon homologation of vitamin A aldehyde (19) is accompHshed by successive acetalizations and enol ether condensations to prepare the aldehyde (46). Metal acetyUde coupling with two molecules of aldehyde (46) completes constmction of the C q carbon framework. Selective reduction of the internal triple bond of (47) is followed by dehydration and thermal isomerization to yield -carotene (21) (Fig. 10). 

Given the relatively rare appearance of oxetanes in natural products, the more powerful functionality of the Patemo-Biichi reaction is the ability to set the relative stereochemistry of multiple centers by cracking or otherwise derivitizing the oxetane ring. Schreiber noted that Patemo—Btlchi reactions of furans with aldehydes followed by acidic hydrolysis generated product 37, tantamount to a threo selective Aldol reaction. This process is referred to as photochemical Aldolization . Schreiber uses this selectivity to establish the absolute stereochemistry of the fused tetrahydrofuran core 44 of the natural product asteltoxin. ... 

A direct application of the ring-opening reaction of an epoxide by a metal enolate amide for the synthesis of a complex molecule can be found in the synthesis of the trisubstituted cyclopentane core of brefeldin A (Scheme 8.35) [68a]. For this purpose, treatment of epoxy amide 137 with excess KH in THF gave a smooth cyclization to amide 138, which was subsequently converted into the natural product. No base/solvent combination that would effect cyclization of the corresponding aldehyde or ester could be found. 

Controlling fluid loss loss is particularly important in the case of the expensive high density brine completion fluids. While copolymers and terpolymers of vinyl monomers such as sodium poly(2-acrylamido-2-methylpropanesulfonate-co-N,N-dimethylacrylamide-coacrylic acid) has been used (H)), hydroxyethyl cellulose is the most commonly used fluid loss additive (11). It is difficult to get most polymers to hydrate in these brines (which may contain less than 50% wt. water). The treatment of HEC particle surfaces with aldehydes such as glyoxal can delay hydration until the HEC particles are well dispersed (12). Slurries in low viscosity oils (13) and alcohols have been used to disperse HEC particles prior to their addition to high density brines. This and the use of hot brines has been found to aid HEC dissolution. Wetting agents such as sulfosuccinate diesters have been found to result in increased permeability in cores invaded by high density brines (14). 

Remarkably, alkylation of the core of a dendrimer of generation 6 (two P = N-P(S) fragments on the core, 64 for the fifth generation, and an upper generation incorporating 256 terminal aldehyde groups) can be performed. This clearly demonstrates that the core of this sixth generation dendrimer is available for certain reactions. 

A fourfold anionic domino process consistingofadominoMichael/aldol/Michael/ aldol process was used by Koo and coworkers for the synthesis of bicyclo[3.3.1]non-anes. They employed 2 equiv. of inexpensive ethyl acetoacetate and 1 equiv. of a simple a, 3-unsaturated aldehyde [290]. Differently substituted dihydroquinolines were assembled in a Michael/aldol/elimination/Friedel-Crafts-type alkylation protocol by the Wessel group [291]. An impressive approach in this field, namely the construction of the indole moiety 2-557, which represents the middle core of the man-zamines, has been published by Marko and coworkers [292]. Manzamine A (2-555) and B (2-556) are members of this unique family of indole alkaloids which were isolated from sponges of the genus Haliclona and Pelina (Scheme 2.126) [293]. 

As expected, some sequences also occur where a domino anionic/pericyclic process is followed by another bond-forming reaction. An example of this is an anionic/per-icyclic/anionic sequence such as the domino iminium ion formation/aza-Cope/ imino aldol (Mannich) process, which has often been used in organic synthesis, especially to construct the pyrrolidine framework. The group of Brummond [450] has recently used this approach to synthesize the core structure 2-885 of the immunosuppressant FR 901483 (2-886) [451] (Scheme 2.197). The process is most likely initiated by the acid-catalyzed formation of the iminium ion 2-882. There follows an aza-Cope rearrangement to produce 2-883, which cyclizes under formation of the aldehyde 2-884. As this compound is rather unstable, it was transformed into the stable acetal 2-885. The proposed intermediate 2-880 is quite unusual as it does not obey Bredf s rule. Recently, this approach was used successfully for a formal total synthesis of FR 901483 2-886 [452]. 

Dendritic molecules with a single triethylene amine core surrounded by hyperbranched polyether sectors catalyze the nitro-aldol reaction between aromatic aldehydes and nitroalkanes (Eq. 3.5).15 The activity of the catalysts decreases when the generation number increases. No significant changes in stereo-control are observed on passing from lower- to higher-generation dendrimers. 

Numerous other aldehyde condensation reactions of five-membered heterocycles have been utilized in the synthesis of the central pyridine core. Paulmier and co-workers employed the condensation of 3-aminothiophenes 114 with aldehydes to give bis-thiophenylpyridines 115 (Equation 25) <1996JHC9>. 

The tricyclic core of spirotryprostatin B can be formed via formation of the dihydropyrrole 325 <2000AGE4596>. Removal of the silyl protecting group of 322, followed by Dess-Martin oxidation, and reaction of the resultant aldehyde with the potassium salt of the diketopiperazine phosphonate 323 led to formation of the enamide 324. 

An intramolecular azomethine ylide-mediated cyclization has been used to access the core 5 6 5 angular tricyclic structure of martinellic acid by Snider (Equation 113) <20010L4217>. Reaction of IV-benzylglycine 420 with the aldehyde 419 led to intramolecular cyclization, giving 421 in good yield. 

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